# created January 2017
from __future__ import division
import math
import random
import warnings
[docs]
class FourElement(object):
"""This class contains attributes and functions for four element model
This model adds another element for the roof. Roofs commonly exhibit the
same excitations as exterior walls but have different coefficients of heat
transfer due to their orientation. Thus the model distinguishes
between internal thermal masses and exterior walls divided into
outerwalls (vertical), rooftops and ground plates. While all exterior walls
contribute to heat transfer to the ambient, adiabatic
conditions apply to interior walls. This approach allows considering the
dynamic behaviour induced by internal heat storage. This class calculates
and holds all attributes given in documentation.
It treats OuterWalls, Rooftops and GroundFloors separate resulting in three
RC-combination for these.
Depending on the chosen method it will consider an extra resistance for
windows or merge all windows into the RC-Combination for outer walls.
Parameters
----------
thermal_zone: ThermalZone()
TEASER instance of ThermalZone
merge_windows : boolean
True for merging windows into the outer wall's RC-combination,
False for separate resistance for window, default is False. (Only
supported for IBPSA)
t_bt : float [d]
Time constant according to VDI 6007 (default t_bt = 5)
Attributes
----------
Interior Walls
area_iw : float [m2]
Area of all interior walls.
alpha_conv_inner_iw : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of interior
walls facing the inside of this thermal zone.
alpha_rad_inner_iw : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of interior
walls facing the inside of this thermal zone.
alpha_comb_inner_iw : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of interior walls
facing the inside of this thermal zone.
alpha_conv_outer_iw : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of interior
walls facing the adjacent thermal zone. (Currently not supported)
alpha_rad_outer_iw : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of interior
walls facing the adjacent thermal zone. (Currently not supported)
alpha_comb_outer_iw : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of interior walls
facing the adjacent thermal zone. (Currently not supported)
ua_value_iw : float [W/K]
U-Value times interior wall area. (Does not take adjacent thermal
zones into account)
r_conv_inner_iw : float [K/W]
Sum of convective resistances for all interior walls
facing the inside of this thermal zone.
r_rad_inner_iw : float [K/W]
Sum of radiative resistances for all interior walls facing the
inside of this thermal zone
r_comb_inner_iw : float [K/W]
Sum of combined resistances for all interior walls facing the
inside of this thermal zone
r1_iw : float [K/W]
Lumped resistance of interior walls no heat transfer coefficients for
convection and radiation are accounted in this resistance.
c1_iw : float [J/K]
Lumped capacity of interior walls
Outer Walls
area_ow : float [m2]
Area of all outer walls .
alpha_conv_inner_ow : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of outer walls
facing the inside of this thermal zone .
alpha_rad_inner_ow : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of outer walls
facing the inside of this thermal zone .
alpha_comb_inner_ow : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of outer walls
facing the inside of this thermal zone .
alpha_conv_outer_ow : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of outer walls
facing the ambient.
alpha_rad_outer_ow : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of outer walls
facing the ambient .
alpha_comb_outer_ow : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of outer walls
facing the ambient.
ua_value_ow : float [W/K]
U-Value times outer wall area.
r_conv_inner_ow : float [K/W]
Sum of convective resistances for all outer walls facing the
inside of this thermal zone .
r_rad_inner_ow : float [K/W]
Sum of radiative resistances for all outer walls facing the
inside of this thermal zone .
r_comb_inner_ow : float [K/W]
Sum of combined resistances for all outer walls facing the
inside of this thermal zone.
r_conv_outer_ow : float [K/W]
Sum of convective resistances for all outer walls facing the
ambient.
r_rad_outer_ow : float [K/W]
Sum of radiative resistances for all outer walls facing the
ambient.
r_comb_outer_ow : float [K/W]
Sum of combined resistances for all outer walls facing the
ambient.
r1_ow : float [K/W]
Lumped resistance of outer walls no heat transfer coefficients for
convection and radiation are accounted in this resistance.
r_rest_ow : float [K/W]
Lumped remaining resistance of outer walls between r1_ow and c1_ow no
heat transfer coefficients for convection and radiation are accounted
in this resistance.
c1_ow : float [J/K]
Lumped capacity of outer walls .
weightfactor_ow : list of floats
Weightfactors of outer walls (UA-Value of walls with same orientation
and tilt divided by ua_value_ow)
outer_wall_areas : list of floats [m2]
Area of all outer walls in one list.
ir_emissivity_outer_ow : float
Area-weighted ir emissivity of outer wall facing the ambient.
ir_emissivity_inner_ow : float
Area-weighted ir emissivity of outer walls facing the thermal zone.
solar_absorp_ow : float
Area-weighted solar absorption of outer walls facing the ambient.
Ground Floors
area_gf : float [m2]
Area of all ground floors.
alpha_conv_inner_gf : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of ground floors
facing the inside of this thermal zone.
alpha_rad_inner_gf : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of ground floors
facing the inside of this thermal zone.
alpha_comb_inner_gf : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of ground floors
facing the inside of this thermal zone.
ua_value_gf : float [W/K]
U-Value times ground floor area.
r_conv_inner_gf : float [K/W]
Sum of convective resistances for all ground floors facing the
inside of this thermal zone.
r_rad_inner_gf : float [K/W]
Sum of radiative resistances for all ground floors facing the
inside of this thermal zone.
r_comb_inner_gf : float [K/W]
Sum of combined resistances for all ground floors facing the
inside of this thermal zone.
r1_gf : float [K/W]
Lumped resistance of ground floors no heat transfer coefficients for
convection and radiation are accounted in this resistance.
r_rest_gf : float [K/W]
Lumped remaining resistance of ground floors between r1_gf and c1_gf no
heat transfer coefficients for convection and radiation are accounted
in this resistance.
c1_gf : float [J/K]
Lumped capacity of ground floors.
weightfactor_gf : float
Weightfactor of ground floors (UA-Value of walls with same orientation
and tilt divided by ua_value_gf)
ground_floor_area : float [m2]
Area of all ground floors.
r_rad_gf_iw : float [K/W]
Resistance for radiative heat transfer between walls.
TODO: needs to be checked
ir_emissivity_inner_gf : float
Area-weighted ir emissivity of ground floors facing the thermal zone.
Rooftops
area_rt : float [m2]
Area of all rooftops .
alpha_conv_inner_rt : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of rooftops
facing the inside of this thermal zone .
alpha_rad_inner_rt : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of rooftops
facing the inside of this thermal zone .
alpha_comb_inner_rt : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of rooftops
facing the inside of this thermal zone .
alpha_conv_outer_rt : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of rooftops
facing the ambient.
alpha_rad_outer_rt : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of rooftops
facing the ambient .
alpha_comb_outer_rt : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of rooftops
facing the ambient.
ua_value_rt : float [W/K]
U-Value times outer wall area.
r_conv_inner_rt : float [K/W]
Sum of convective resistances for all rooftops facing the
inside of this thermal zone .
r_rad_inner_rt : float [K/W]
Sum of radiative resistances for all rooftops facing the
inside of this thermal zone .
r_comb_inner_rt : float [K/W]
Sum of combined resistances for all rooftops facing the
inside of this thermal zone.
r_conv_outer_rt : float [K/W]
Sum of convective resistances for all rooftops facing the
ambient.
r_rad_outer_rt : float [K/W]
Sum of radiative resistances for all rooftops facing the
ambient.
r_comb_outer_rt : float [K/W]
Sum of combined resistances for all rooftops facing the
ambient.
r1_rt : float [K/W]
Lumped resistance of rooftops no heat transfer coefficients for
convection and radiation are accounted in this resistance.
r_rest_rt : float [K/W]
Lumped remaining resistance of rooftops between r1_rt and c1_rt no
heat transfer coefficients for convection and radiation are accounted
in this resistance.
c1_rt : float [J/K]
Lumped capacity of rooftops .
weightfactor_rt : list of floats
Weightfactors of rooftops (UA-Value of walls with same orientation
and tilt divided by ua_value_rt)
weightfactor_win_rt : list of floats
Weightfactors of windows in rooftop. CAUTION: this will be always a
list full of zeors, as windows are always calculated separatly.
outer_wall_areas : list of floats [m2]
Area of all rooftops in one list.
r_rad_rt_iw : float [K/W]
Resistance for radiative heat transfer between walls.
TODO: needs to be checked
ir_emissivity_outer_rt : float
Area-weighted ir emissivity of outer wall facing the ambient.
ir_emissivity_inner_rt : float
Area-weighted ir emissivity of rooftops facing the thermal zone.
solar_absorp_rt : float
Area-weighted solar absorption of rooftops facing the ambient.
tilt_rt : list of floats [degree]
Tilt of rooftops against the horizontal.
orientation_rt : list of floats [degree]
Orientation of rooftops (Azimuth).
0 - North
90 - East
180 - South
270 - West
Windows
area_win : float [m2]
Area of all windows.
alpha_conv_inner_win : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of windows
facing the inside of this thermal zone.
alpha_rad_inner_win : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of windows
facing the inside of this thermal zone.
alpha_comb_inner_win : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of windows facing
the inside of this thermal zone.
ratio_conv_rad_inner_win : float [-]
Ratio for windows between convective and radiative heat emission,
given in VDI 6007-3
alpha_conv_outer_win : float [W/(m2K)]
Area-weighted convective coefficient of heat transfer of windows
facing the ambient.
alpha_rad_outer_win : float [W/(m2K)]
Area-weighted radiative coefficient of heat transfer of windows
facing the ambient.
alpha_comb_outer_win : float [W/(m2K)]
Area-weighted combined coefficient of heat transfer of windows facing
the ambient.
ua_value_win : float [W/K]
U-Value times outer wall area.
u_value_win : float [W/(m2K)]
Area weighted U-Value of windows.
r_conv_inner_win : float [K/W]
Sum of convective resistances for all windows facing the
inside of this thermal zone.
r_rad_inner_win : float [K/W]
Sum of radiative resistances for all windows facing the
inside of this thermal zone.
r_comb_inner_win : float [K/W]
Sum of combined resistances for all windows facing the
inside of this thermal zone.
r_conv_outer_win : float [K/W]
Sum of convective resistances for all windows facing the
ambient.
r_rad_outer_win : float [K/W]
Sum of radiative resistances for all windows facing the
ambient.
r_comb_outer_win : float [K/W]
Sum of combined resistances for all windows facing the
ambient.
r1_win : float [K/W]
Lumped resistance of windows, no heat transfer coefficients for
convection and radiation are accounted in this resistance.
weightfactor_win : list of floats
Weightfactors of windows (UA-Value of windows with same orientation
and tilt divided by ua_value_win or ua_value_win+ua_value_ow,
depending if windows is lumped/merged into the walls or not)
window_areas : list of floats [m2]
Area of all windows in one list, if the windows are merged into the
outer wall this list will be full of zeros
transparent_areas : list of floats [m2]
Area of all transparent elements (most likely windows) in one list,
this list will be always filled with the areas, independent if
windows are merged into walls or not.
solar_absorp_win : float
Area-weighted solar absorption for windows. (typically 0.0)
ir_emissivity_win : float
Area-weighted ir_emissivity for windows. Can be used for windows
facing the thermal zone and the ambient.
weighted_g_value : float
Area-weighted g-Value of all windows.
shading_max_irr : list of float [W/m2]
Threshold value above which the sunblind becomes active for the whole zone.
Threshold regards to the incoming irradiation level with the window direction.
This value does not account for heat flux due to the outside temperature.
shading_g_total : list of float
Factor representing how much of the actual solar irradiation goes through
the sunblind and enters the window element, for the case, that the sunblind is
activated. Defaults to 1, i.e. no shading is active.
Misc values:
alpha_rad_inner_mean : float [W/(m2K)]
Area-weighted radiative coefficient of all surfaces facing the
inside of this thermal zone (OuterWalls, Windows, InnerWalls, ...).
alpha_rad_outer_mean : float [W/(m2K)]
Area-weighted radiative coefficient of all surfaces facing the
ambient (OuterWalls, Windows, ...).
heat_load : [W]
Static heat load of the thermal zone.
heat_load_outside_factor : float [W/K]
Factor needed for recalculation of the heat load of the thermal zone.
This can be used to recalculate the thermalzones heat load inside
Modelica export for parametric studies. This works only together with
heat_load_ground_factor.
heat_load = heat_load_outside_factor * (t_inside - t_outside) +
heat_load_ground_factor * (t_inside - t_ground).
heat_load_ground_factor : float [W/K]
Factor needed for recalculation of the heat load of the thermal zone.
This can be used to recalculate the thermalzones heat load inside
Modelica export for parametric studies. See heat_load_outside_factor.
facade_areas : list of floats [m2]
List containing the area of each facade (with same tilt and
orientation) this includes also roofs and ground floors and windows.
n_outer : int
Number of total facades with different combination of tilt and
orientation, windows and outer walls
n_rt : int
Number of total facades with different combination of tilt and
orientation, Rooftops
tilt_facade : list of floats [degree]
Tilt of facades against the horizontal.
orientation_facade : list of floats [degree]
Orientation of facades (Azimuth).
0 - North
90 - East
180 - South
270 - West
"""
def __init__(self, thermal_zone, merge_windows, t_bt):
"""Constructor for TwoElement"""
self.internal_id = random.random()
self.thermal_zone = thermal_zone
self.merge_windows = merge_windows
self.t_bt = t_bt
# Attributes of inner walls
self.area_iw = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_iw = 0.0
self.alpha_rad_inner_iw = 0.0
self.alpha_comb_inner_iw = 0.0
# coefficient of heat transfer facing the adjacent thermal zone
self.alpha_conv_outer_iw = 0.0
self.alpha_rad_outer_iw = 0.0
self.alpha_comb_outer_iw = 0.0
# UA-Value
self.ua_value_iw = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_iw = 0.0
self.r_rad_inner_iw = 0.0
self.r_comb_inner_iw = 0.0
self.r_conv_outer_iw = 0.0
self.r_rad_outer_iw = 0.0
self.r_comb_outer_iw = 0.0
# lumped resistance/capacity
self.r1_iw = 0.0
self.c1_iw = 0.0
# Attributes for outer walls
self.area_ow = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_ow = 0.0
self.alpha_rad_inner_ow = 0.0
self.alpha_comb_inner_ow = 0.0
# coefficient of heat transfer facing the ambient
self.alpha_conv_outer_ow = 0.0
self.alpha_rad_outer_ow = 0.0
self.alpha_comb_outer_ow = 0.0
# UA-Value
self.ua_value_ow = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_ow = 0.0
self.r_rad_inner_ow = 0.0
self.r_comb_inner_ow = 0.0
# resistances for heat transfer facing the ambient
self.r_conv_outer_ow = 0.0
self.r_rad_outer_ow = 0.0
self.r_comb_outer_ow = 0.0
# lumped resistances/capacity
self.r1_ow = 0.0
self.r_rest_ow = 0.0
self.c1_ow = 0.0
self.r_total_ow = 0.0
# Optical properties
self.ir_emissivity_outer_ow = 0.0
self.ir_emissivity_inner_ow = 0.0
self.solar_absorp_ow = 0.0
# Additional attributes
self.weightfactor_ow = []
self.weightfactor_ground = 0.0
self.outer_wall_areas = []
# Attributes for GroundFloor
self.area_gf = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_gf = 0.0
self.alpha_rad_inner_gf = 0.0
self.alpha_comb_inner_gf = 0.0
# UA-Value
self.ua_value_gf = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_gf = 0.0
self.r_rad_inner_gf = 0.0
self.r_comb_inner_gf = 0.0
# lumped resistances/capacity
self.r1_gf = 0.0
self.r_rest_gf = 0.0
self.c1_gf = 0.0
self.r_total_gf = 0.0
# Optical properties
self.ir_emissivity_inner_gf = 0.0
# Additional attributes
self.weightfactor_ground = 0.0
# Attributes for rooftops
self.area_rt = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_rt = 0.0
self.alpha_rad_inner_rt = 0.0
self.alpha_comb_inner_rt = 0.0
# coefficient of heat transfer facing the ambient
self.alpha_conv_outer_rt = 0.0
self.alpha_rad_outer_rt = 0.0
self.alpha_comb_outer_rt = 0.0
# UA-Value
self.ua_value_rt = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_rt = 0.0
self.r_rad_inner_rt = 0.0
self.r_comb_inner_rt = 0.0
# resistances for heat transfer facing the ambient
self.r_conv_outer_rt = 0.0
self.r_rad_outer_rt = 0.0
self.r_comb_outer_rt = 0.0
# lumped resistances/capacity
self.r1_rt = 0.0
self.r_rest_rt = 0.0
self.c1_rt = 0.0
self.r_total_rt = 0.0
# Optical properties
self.ir_emissivity_outer_rt = 0.0
self.ir_emissivity_inner_rt = 0.0
self.solar_absorp_rt = 0.0
# Additional attributes
self.weightfactor_rt = []
self.weightfactor_win_rt = []
self.rooftop_areas = []
self.tilt_rt = []
self.orientation_rt = []
# TODO: check this value
self.r_rad_rt_iw = 0.0
# Attributes for windows
self.area_win = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_win = 0.0
self.alpha_rad_inner_win = 0.0
self.alpha_comb_inner_win = 0.0
self.ratio_conv_rad_inner_win = 0.0
# coefficient of heat transfer facing the ambient
self.alpha_conv_outer_win = 0.0
self.alpha_rad_outer_win = 0.0
self.alpha_comb_outer_win = 0.0
# UA-Value
self.ua_value_win = 0.0
self.u_value_win = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_win = 0.0
self.r_rad_inner_win = 0.0
self.r_comb_inner_win = 0.0
# resistances for heat transfer facing the ambient
self.r_conv_outer_win = 0.0
self.r_rad_outer_win = 0.0
self.r_comb_outer_win = 0.0
# lumped resistances/capacity
self.r1_win = 0.0
# Optical properties
self.ir_emissivity_win = 0.0
self.ir_emissivity_inner_win = 0.0
self.solar_absorp_win = 0.0
# Additional attributes
self.weightfactor_win = []
self.window_areas = []
self.transparent_areas = []
self.shading_g_total = []
self.shading_max_irr = []
self.weighted_g_value = 0.0
# Misc values
self.alpha_rad_inner_mean = 0.0
self.alpha_rad_outer_mean = 0.0
self.n_outer = 0
self.n_rt = 0
self.facade_areas = []
self.tilt_facade = []
self.orientation_facade = []
self.heat_load = 0.0
self.cool_load = 0.0
self.heat_load_outside_factor = 0.0
self.heat_load_ground_factor = 0.0
[docs]
def calc_attributes(self):
"""Calls all necessary function to calculate model attributes"""
for out_wall in self.thermal_zone.outer_walls:
out_wall.calc_equivalent_res()
out_wall.calc_ua_value()
for rt in self.thermal_zone.rooftops:
rt.calc_equivalent_res()
rt.calc_ua_value()
for gf in self.thermal_zone.ground_floors:
gf.calc_equivalent_res()
gf.calc_ua_value()
for win in self.thermal_zone.windows:
win.calc_equivalent_res()
win.calc_ua_value()
for inner_wall in (
self.thermal_zone.inner_walls
+ self.thermal_zone.floors
+ self.thermal_zone.ceilings
):
inner_wall.calc_equivalent_res()
inner_wall.calc_ua_value()
self.set_calc_default()
if len(self.thermal_zone.outer_walls) < 1:
warnings.warn(
"No walls are defined as outer walls for thermal "
+ "zone "
+ self.thermal_zone.name
+ " in building "
+ self.thermal_zone.parent.name
+ ", please be careful with results. In addition "
+ "this might lead to RunTimeErrors"
)
else:
self._sum_outer_wall_elements()
if (
len(
self.thermal_zone.inner_walls
+ self.thermal_zone.floors
+ self.thermal_zone.ceilings
)
< 1
):
warnings.warn(
"For thermal zone "
+ self.thermal_zone.name
+ " in building "
+ self.thermal_zone.parent.name
+ ", no inner walls have been defined."
)
else:
self._sum_inner_wall_elements()
self._calc_inner_elements()
if len(self.thermal_zone.windows) < 1:
warnings.warn(
"For thermal zone "
+ self.thermal_zone.name
+ " in building "
+ self.thermal_zone.parent.name
+ ", no windows have been defined."
)
else:
self._sum_window_elements()
if len(self.thermal_zone.ground_floors) < 1:
warnings.warn(
"For thermal zone "
+ self.thermal_zone.name
+ " in building "
+ self.thermal_zone.parent.name
+ ", no ground floors have been defined."
)
else:
self._sum_ground_floor_elements()
self._calc_ground_floor_elements()
if len(self.thermal_zone.rooftops) < 1:
warnings.warn(
"For thermal zone "
+ self.thermal_zone.name
+ " in building "
+ self.thermal_zone.parent.name
+ ", no rooftops have been defined."
)
else:
self._sum_rooftop_elements()
self._calc_rooftop_elements()
if (
len(self.thermal_zone.outer_walls) >= 1
or len(self.thermal_zone.windows) >= 1
):
self._calc_outer_elements()
self._calc_wf()
self._calc_mean_values()
self._calc_number_of_elements()
self._fill_zone_lists()
self._calc_heat_load()
self.cool_load = -self.heat_load
return True
@staticmethod
def _calc_parallel_connection(element_list, omega):
"""Parallel connection of walls according to VDI 6007
Calculates the parallel connection of wall elements according to VDI
6007, resulting in R1 and C1 (equation 23, 24).
Parameters
----------
element_list : list
List of inner or outer walls
omega : float
VDI 6007 frequency
Returns
-------
r1 : float [K/W]
VDI 6007 resistance for all inner or outer walls
c1 : float [K/W]
VDI 6007 capacity all for inner or outer walls
"""
for wall_count in range(len(element_list) - 1):
if wall_count == 0:
r1 = (
element_list[wall_count].r1 * element_list[wall_count].c1 ** 2
+ element_list[wall_count + 1].r1
* element_list[wall_count + 1].c1 ** 2
+ omega ** 2
* element_list[wall_count].r1
* element_list[wall_count + 1].r1
* (element_list[wall_count].r1 + element_list[wall_count + 1].r1)
* element_list[wall_count].c1 ** 2
* element_list[wall_count + 1].c1 ** 2
) / (
(element_list[wall_count].c1 + element_list[wall_count + 1].c1) ** 2
+ omega ** 2
* (element_list[wall_count].r1 + element_list[wall_count + 1].r1)
** 2
* element_list[wall_count].c1 ** 2
* element_list[wall_count + 1].c1 ** 2
)
c1 = (
(element_list[wall_count].c1 + element_list[wall_count + 1].c1) ** 2
+ omega ** 2
* (element_list[wall_count].r1 + element_list[wall_count + 1].r1)
** 2
* element_list[wall_count].c1 ** 2
* element_list[wall_count + 1].c1 ** 2
) / (
element_list[wall_count].c1
+ element_list[wall_count + 1].c1
+ omega ** 2
* (
element_list[wall_count].r1 ** 2 * element_list[wall_count].c1
+ element_list[wall_count + 1].r1 ** 2
* element_list[wall_count + 1].c1
)
* element_list[wall_count].c1
* element_list[wall_count + 1].c1
)
else:
r1x = r1
c1x = c1
r1 = (
r1x * c1x ** 2
+ element_list[wall_count + 1].r1
* element_list[wall_count + 1].c1 ** 2
+ omega ** 2
* r1x
* element_list[wall_count + 1].r1
* (r1x + element_list[wall_count + 1].r1)
* c1x ** 2
* element_list[wall_count + 1].c1 ** 2
) / (
(c1x + element_list[wall_count + 1].c1) ** 2
+ omega ** 2
* (r1x + element_list[wall_count + 1].r1) ** 2
* c1x ** 2
* element_list[wall_count + 1].c1 ** 2
)
c1 = (
(c1x + element_list[wall_count + 1].c1) ** 2
+ omega ** 2
* (r1x + element_list[wall_count + 1].r1) ** 2
* c1x ** 2
* element_list[wall_count + 1].c1 ** 2
) / (
c1x
+ element_list[wall_count + 1].c1
+ omega ** 2
* (
r1x ** 2 * c1x
+ element_list[wall_count + 1].r1 ** 2
* element_list[wall_count + 1].c1
)
* c1x
* element_list[wall_count + 1].c1
)
return r1, c1
def _sum_outer_wall_elements(self):
"""Sum attributes for outer wall elements
This function sums and computes the area-weighted values,
where necessary for coefficients of heat
transfer, resistances, areas and UA-Values.
For ThreeElement model it treats rooftops and outer walls
as one kind of wall type.
"""
self.area_ow = sum(out_wall.area for out_wall in self.thermal_zone.outer_walls)
self.ua_value_ow = sum(
out_wall.ua_value for out_wall in self.thermal_zone.outer_walls
)
self.r_total_ow = 1 / self.ua_value_ow
# values facing the inside of the thermal zone
self.r_conv_inner_ow = 1 / (
sum(1 / out_wall.r_inner_conv for out_wall in self.thermal_zone.outer_walls)
)
self.r_rad_inner_ow = 1 / (
sum(1 / out_wall.r_inner_rad for out_wall in self.thermal_zone.outer_walls)
)
self.r_comb_inner_ow = 1 / (
sum(1 / out_wall.r_inner_comb for out_wall in self.thermal_zone.outer_walls)
)
self.ir_emissivity_inner_ow = (
sum(
out_wall.layer[0].material.ir_emissivity * out_wall.area
for out_wall in self.thermal_zone.outer_walls
)
) / self.area_ow
self.alpha_conv_inner_ow = 1 / (self.r_conv_inner_ow * self.area_ow)
self.alpha_rad_inner_ow = 1 / (self.r_rad_inner_ow * self.area_ow)
self.alpha_comb_inner_ow = 1 / (self.r_comb_inner_ow * self.area_ow)
# values facing the ambient
# ground floor does not have any coefficients on ambient side
self.r_conv_outer_ow = 1 / (
sum(1 / out_wall.r_outer_conv for out_wall in self.thermal_zone.outer_walls)
)
self.r_rad_outer_ow = 1 / (
sum(1 / out_wall.r_outer_rad for out_wall in self.thermal_zone.outer_walls)
)
self.r_comb_outer_ow = 1 / (
sum(1 / out_wall.r_outer_comb for out_wall in self.thermal_zone.outer_walls)
)
self.ir_emissivity_outer_ow = (
(
sum(
out_wall.layer[-1].material.ir_emissivity * out_wall.area
for out_wall in self.thermal_zone.outer_walls
)
)
) / self.area_ow
self.solar_absorp_ow = (
(
sum(
out_wall.layer[-1].material.solar_absorp * out_wall.area
for out_wall in self.thermal_zone.outer_walls
)
)
) / self.area_ow
self.alpha_conv_outer_ow = 1 / (self.r_conv_outer_ow * self.area_ow)
self.alpha_rad_outer_ow = 1 / (self.r_rad_outer_ow * self.area_ow)
self.alpha_comb_outer_ow = 1 / (self.r_comb_outer_ow * self.area_ow)
def _sum_ground_floor_elements(self):
"""Sum attributes for ground floor elements
This function sums and computes the area-weighted values,
where necessary (the class doc string) for coefficients of heat
transfer, resistances, areas and UA-Values.
"""
self.area_gf = sum(ground.area for ground in self.thermal_zone.ground_floors)
self.ua_value_gf = sum(
ground.ua_value for ground in self.thermal_zone.ground_floors
)
self.r_total_gf = 1 / self.ua_value_gf
# values facing the inside of the thermal zone
self.r_conv_inner_gf = 1 / sum(
1 / ground.r_inner_conv for ground in self.thermal_zone.ground_floors
)
self.r_rad_inner_gf = 1 / sum(
1 / ground.r_inner_rad for ground in self.thermal_zone.ground_floors
)
self.r_comb_inner_gf = 1 / sum(
1 / ground.r_inner_comb for ground in self.thermal_zone.ground_floors
)
self.ir_emissivity_inner_gf = (
sum(
ground.layer[0].material.ir_emissivity * ground.area
for ground in self.thermal_zone.ground_floors
)
/ self.area_gf
)
self.alpha_conv_inner_gf = 1 / (self.r_conv_inner_gf * self.area_gf)
self.alpha_rad_inner_gf = 1 / (self.r_rad_inner_gf * self.area_gf)
self.alpha_comb_inner_gf = 1 / (self.r_comb_inner_gf * self.area_gf)
def _sum_rooftop_elements(self):
"""Sum attributes for rooftop elements
This function sums and computes the area-weighted values,
where necessary for coefficients of heat
transfer, resistances, areas and UA-Values.
For ThreeElement model it treats rooftops and outer walls
as one kind of wall type.
"""
self.area_rt = sum(roof.area for roof in self.thermal_zone.rooftops)
self.ua_value_rt = sum(roof.ua_value for roof in self.thermal_zone.rooftops)
self.r_total_rt = 1 / self.ua_value_rt
# values facing the inside of the thermal zone
self.r_conv_inner_rt = 1 / sum(
1 / roof.r_inner_conv for roof in self.thermal_zone.rooftops
)
self.r_rad_inner_rt = 1 / sum(
1 / roof.r_inner_rad for roof in self.thermal_zone.rooftops
)
self.r_comb_inner_rt = 1 / sum(
1 / roof.r_inner_comb for roof in self.thermal_zone.rooftops
)
self.ir_emissivity_inner_rt = (
sum(
roof.layer[0].material.ir_emissivity * roof.area
for roof in self.thermal_zone.rooftops
)
/ self.area_rt
)
self.alpha_conv_inner_rt = 1 / (self.r_conv_inner_rt * self.area_rt)
self.alpha_rad_inner_rt = 1 / (self.r_rad_inner_rt * self.area_rt)
self.alpha_comb_inner_rt = 1 / (self.r_comb_inner_rt * self.area_rt)
# values facing the ambient
# ground floor does not have any coefficients on ambient side
self.r_conv_outer_rt = 1 / sum(
1 / roof.r_outer_conv for roof in self.thermal_zone.rooftops
)
self.r_rad_outer_rt = 1 / sum(
1 / roof.r_outer_rad for roof in self.thermal_zone.rooftops
)
self.r_comb_outer_rt = 1 / sum(
1 / roof.r_outer_comb for roof in self.thermal_zone.rooftops
)
self.ir_emissivity_outer_rt = (
sum(
roof.layer[-1].material.ir_emissivity * roof.area
for roof in self.thermal_zone.rooftops
)
/ self.area_rt
)
self.solar_absorp_rt = (
sum(
roof.layer[-1].material.solar_absorp * roof.area
for roof in self.thermal_zone.rooftops
)
/ self.area_rt
)
self.alpha_conv_outer_rt = 1 / (self.r_conv_outer_rt * self.area_rt)
self.alpha_rad_outer_rt = 1 / (self.r_rad_outer_rt * self.area_rt)
self.alpha_comb_outer_rt = 1 / (self.r_comb_outer_rt * self.area_rt)
def _sum_inner_wall_elements(self):
"""Sum attributes for interior elements
This function sums and computes the area-weighted values,
where necessary (the class doc string) for coefficients of heat
transfer, resistances, areas and UA-Values.
It treats all inner walls identical.
Function is identical for TwoElement, ThreeElement and FourElement.
Calculation of adjacent thermal zones and thus these attributes are
currently not supported.
"""
self.area_iw = (
sum(in_wall.area for in_wall in self.thermal_zone.inner_walls)
+ sum(floor.area for floor in self.thermal_zone.floors)
+ sum(ceiling.area for ceiling in self.thermal_zone.ceilings)
)
self.ua_value_iw = (
sum(in_wall.ua_value for in_wall in self.thermal_zone.inner_walls)
+ sum(floor.ua_value for floor in self.thermal_zone.floors)
+ sum(ceiling.ua_value for ceiling in self.thermal_zone.ceilings)
)
# values facing the inside of the thermal zone
self.r_conv_inner_iw = 1 / (
sum(1 / in_wall.r_inner_conv for in_wall in self.thermal_zone.inner_walls)
+ sum(1 / floor.r_inner_conv for floor in self.thermal_zone.floors)
+ sum(1 / ceiling.r_inner_conv for ceiling in self.thermal_zone.ceilings)
)
self.r_rad_inner_iw = 1 / (
sum(1 / in_wall.r_inner_rad for in_wall in self.thermal_zone.inner_walls)
+ sum(1 / floor.r_inner_rad for floor in self.thermal_zone.floors)
+ sum(1 / ceiling.r_inner_rad for ceiling in self.thermal_zone.ceilings)
)
self.r_comb_inner_iw = 1 / (
sum(1 / in_wall.r_inner_comb for in_wall in self.thermal_zone.inner_walls)
+ sum(1 / floor.r_inner_comb for floor in self.thermal_zone.floors)
+ sum(1 / ceiling.r_inner_comb for ceiling in self.thermal_zone.ceilings)
)
self.ir_emissivity_inner_iw = (
sum(
in_wall.layer[0].material.ir_emissivity * in_wall.area
for in_wall in self.thermal_zone.inner_walls
)
+ sum(
floor.layer[0].material.ir_emissivity * floor.area
for floor in self.thermal_zone.floors
)
+ sum(
ceiling.layer[0].material.ir_emissivity * ceiling.area
for ceiling in self.thermal_zone.ceilings
)
) / self.area_iw
self.alpha_conv_inner_iw = 1 / (self.r_conv_inner_iw * self.area_iw)
self.alpha_rad_inner_iw = 1 / (self.r_rad_inner_iw * self.area_iw)
self.alpha_comb_inner_iw = 1 / (self.r_comb_inner_iw * self.area_iw)
# adjacent thermal zones are not supported!
def _sum_window_elements(self):
"""Sum attributes for window elements
This function sums and computes the area-weighted values,
where necessary (the class doc string) for coefficients of heat
transfer, resistances, areas and UA-Values.
Function is identical for TwoElement, ThreeElement and FourElement.
"""
self.area_win = sum(win.area for win in self.thermal_zone.windows)
self.ua_value_win = sum(win.ua_value for win in self.thermal_zone.windows)
self.u_value_win = self.ua_value_win / self.area_win
# values facing the inside of the thermal zone
self.r_conv_inner_win = 1 / (
sum(1 / win.r_inner_conv for win in self.thermal_zone.windows)
)
self.r_rad_inner_win = 1 / (
sum(1 / win.r_inner_rad for win in self.thermal_zone.windows)
)
self.r_comb_inner_win = 1 / (
sum(1 / win.r_inner_comb for win in self.thermal_zone.windows)
)
self.ir_emissivity_inner_win = (
sum(
win.layer[0].material.ir_emissivity * win.area
for win in self.thermal_zone.windows
)
/ self.area_win
)
self.alpha_conv_inner_win = 1 / (self.r_conv_inner_win * self.area_win)
self.alpha_rad_inner_win = 1 / (self.r_rad_inner_win * self.area_win)
self.alpha_comb_inner_win = 1 / (self.r_comb_inner_win * self.area_win)
self.ratio_conv_rad_inner_win = (
sum(win.a_conv * win.area for win in self.thermal_zone.windows)
/ self.area_win
)
# values facing the ambient
self.r_conv_outer_win = 1 / (
sum(1 / win.r_outer_conv for win in self.thermal_zone.windows)
)
self.r_rad_outer_win = 1 / (
sum(1 / win.r_outer_rad for win in self.thermal_zone.windows)
)
self.r_comb_outer_win = 1 / (
sum(1 / win.r_outer_comb for win in self.thermal_zone.windows)
)
self.ir_emissivity_win = (
sum(
win.layer[-1].material.ir_emissivity * win.area
for win in self.thermal_zone.windows
)
/ self.area_win
)
self.solar_absorp_win = (
sum(
win.layer[-1].material.solar_absorp * win.area
for win in self.thermal_zone.windows
)
/ self.area_win
)
self.weighted_g_value = (
sum(win.g_value * win.area for win in self.thermal_zone.windows)
/ self.area_win
)
self.alpha_conv_outer_win = 1 / (self.r_conv_outer_win * self.area_win)
self.alpha_rad_outer_win = 1 / (self.r_rad_outer_win * self.area_win)
self.alpha_comb_outer_win = 1 / (self.r_comb_outer_win * self.area_win)
def _calc_outer_elements(self):
"""Lumped parameter for outer wall elements
Calculates all necessary parameters for outer walls. This includes
OuterWalls and Rooftops.
Attributes
----------
omega : float [1/s]
angular frequency with given time period.
outer_walls : list
List containing all TEASER Wall instances that are treated as same
outer wall type. In case of TwoElement model OuterWalls, Rooftops
"""
omega = 2 * math.pi / 86400 / self.t_bt
outer_walls = self.thermal_zone.outer_walls
if 0 < len(outer_walls) <= 1:
# only one outer wall, no need to calculate chain matrix
self.r1_ow = outer_walls[0].r1
self.c1_ow = outer_walls[0].c1_korr
elif len(outer_walls) > 1:
# more than one outer wall, calculate chain matrix
self.r1_ow, self.c1_ow = self._calc_parallel_connection(outer_walls, omega)
else:
warnings.warn(
"No walls are defined as outer walls, please be "
"careful with results. In addition this might lead "
"to RunTimeErrors"
)
if self.merge_windows is False:
try:
if len(self.thermal_zone.windows) > 0:
self.r1_win = 1 / sum(
(1 / win.r1) for win in self.thermal_zone.windows
)
if len(self.thermal_zone.outer_walls) > 0:
conduction = 1 / sum(
(1 / element.r_conduc) for element in outer_walls
)
self.r_rest_ow = conduction - self.r1_ow
except RuntimeError:
print(
"As no outer walls or no windows are defined lumped "
"parameter cannot be calculated"
)
if self.merge_windows is True:
try:
if (
len(self.thermal_zone.windows) > 0
and len(self.thermal_zone.outer_walls) > 0
):
self.r1_win = 1 / sum(
1 / (win.r1 / 6) for win in self.thermal_zone.windows
)
self.r1_ow = 1 / (1 / self.r1_ow + 1 / self.r1_win)
self.r_total_ow = 1 / (self.ua_value_ow + self.ua_value_win)
self.r_rest_ow = (
self.r_total_ow
- self.r1_ow
- 1
/ (
(
(1 / self.r_conv_inner_ow)
+ (1 / self.r_conv_inner_win)
+ (1 / self.r_rad_inner_ow)
+ (1 / self.r_rad_inner_win)
)
)
) - 1 / (self.alpha_comb_outer_ow * self.area_ow)
self.ir_emissivity_inner_ow = (
self.ir_emissivity_inner_ow * self.area_ow
+ self.ir_emissivity_inner_win * self.area_win
) / (self.area_ow + self.area_win)
self.ir_emissivity_outer_ow = (
self.ir_emissivity_outer_ow * self.area_ow
+ self.ir_emissivity_win * self.area_win
) / (self.area_ow + self.area_win)
self.solar_absorp_ow = (
self.solar_absorp_ow * self.area_ow
+ self.solar_absorp_win * self.area_win
) / (self.area_ow + self.area_win)
except RuntimeError:
print(
"As no outer walls or no windows are defined lumped "
"parameter cannot be calculated"
)
def _calc_ground_floor_elements(self):
"""Lumped parameter for ground floor elements
Calculates lumped parameters for ground floors. No windows in ground
floor allowed.
Attributes
----------
omega : float [1/s]
angular frequency with given time period.
"""
omega = 2 * math.pi / 86400 / self.t_bt
if 0 < len(self.thermal_zone.ground_floors) <= 1:
# only one outer wall, no need to calculate chain matrix
self.r1_gf = self.thermal_zone.ground_floors[0].r1
self.c1_gf = self.thermal_zone.ground_floors[0].c1_korr
elif len(self.thermal_zone.ground_floors) > 1:
# more than one outer wall, calculate chain matrix
self.r1_gf, self.c1_gf = self._calc_parallel_connection(
self.thermal_zone.ground_floors, omega
)
else:
warnings.warn(
"No walls are defined as ground floors, please be "
"careful with results. In addition this might lead "
"to RunTimeErrors"
)
try:
conduction = 1 / sum(
(1 / element.r_conduc) for element in self.thermal_zone.ground_floors
)
self.r_rest_gf = conduction - self.r1_gf
except RuntimeError:
print(
"As no ground floors are defined lumped "
"parameter cannot be calculated"
)
def _calc_rooftop_elements(self):
"""Lumped parameter for ground floor elements
Calculates lumped parameters for rooftops. Windows are considered in
outer wall calculation. This results in an error concerning the
interior radiation distribution. But currently there is no other option.
Attributes
----------
omega : float [1/s]
angular frequency with given time period.
"""
omega = 2 * math.pi / 86400 / self.t_bt
if 0 < len(self.thermal_zone.rooftops) <= 1:
# only one outer wall, no need to calculate chain matrix
self.r1_rt = self.thermal_zone.rooftops[0].r1
self.c1_rt = self.thermal_zone.rooftops[0].c1_korr
elif len(self.thermal_zone.rooftops) > 1:
# more than one outer wall, calculate chain matrix
self.r1_rt, self.c1_rt = self._calc_parallel_connection(
self.thermal_zone.rooftops, omega
)
else:
warnings.warn(
"No walls are defined as ground floors, please be "
"careful with results. In addition this might lead "
"to RunTimeErrors"
)
try:
conduction = 1 / sum(
(1 / element.r_conduc) for element in self.thermal_zone.rooftops
)
self.r_rest_rt = conduction - self.r1_rt
except RuntimeError:
print("As no rooftops are defined lumped " "parameter cannot be calculated")
def _calc_inner_elements(self):
"""Lumped parameter for outer wall elements
Calculates all necessary parameters for inner walls. This includes
InnerWalls, Ceilings and Floors.
Attributes
----------
omega : float [1/s]
angular frequency with given time period.
outer_walls : list
List containing all TEASER Wall instances that are treated as same
outer wall type. In case of TwoElement model OuterWalls,
GroundFloors, Rooftops
"""
omega = 2 * math.pi / 86400 / self.t_bt
inner_walls = (
self.thermal_zone.inner_walls
+ self.thermal_zone.floors
+ self.thermal_zone.ceilings
)
for in_wall in inner_walls:
in_wall.calc_equivalent_res()
in_wall.calc_ua_value()
if 0 < len(inner_walls) <= 1:
# only one outer wall, no need to calculate chain matrix
self.r1_iw = inner_walls[0].r1
self.c1_iw = inner_walls[0].c1_korr
elif len(inner_walls) > 1:
# more than one outer wall, calculate chain matrix
self.r1_iw, self.c1_iw = self._calc_parallel_connection(inner_walls, omega)
else:
warnings.warn(
"No walls are defined as outer walls, please be "
"careful with results. In addition this might lead "
"to RunTimeErrors"
)
def _calc_wf(self):
"""Weightfactors for outer elements(walls, roof, ground floor, windows)
Calculates the weightfactors of outer walls, rooftops, including
ground and windows.
"""
self.weightfactor_ground = 0.0
if self.merge_windows is True:
for wall in self.thermal_zone.outer_walls:
wall.wf_out = wall.ua_value / (self.ua_value_ow + self.ua_value_win)
for win in self.thermal_zone.windows:
win.wf_out = win.ua_value / (self.ua_value_ow + self.ua_value_win)
for rt in self.thermal_zone.rooftops:
rt.wf_out = rt.ua_value / self.ua_value_rt
elif self.merge_windows is False:
for wall in self.thermal_zone.outer_walls:
wall.wf_out = wall.ua_value / self.ua_value_ow
for win in self.thermal_zone.windows:
win.wf_out = win.ua_value / self.ua_value_win
for rt in self.thermal_zone.rooftops:
rt.wf_out = rt.ua_value / self.ua_value_rt
else:
raise ValueError("specify merge window method correctly")
def _calc_mean_values(self):
"""Calculates mean values for inner and outer elements
This function calculates mean values inside the thermal zone (e.g.
the mean value for coefficient of radiative heat transfer between
inner and outer walls
"""
self.alpha_rad_inner_mean = (
self.area_ow * self.alpha_rad_inner_ow
+ self.area_win * self.alpha_rad_inner_win
+ self.area_gf * self.alpha_rad_inner_gf
+ self.area_rt * self.alpha_rad_inner_rt
+ self.area_iw * self.alpha_rad_inner_iw
) / (self.area_ow + self.area_win + self.area_iw + self.area_gf + self.area_rt)
self.alpha_rad_outer_mean = (
self.area_ow * self.alpha_rad_outer_ow
+ self.area_rt * self.alpha_rad_outer_rt
+ self.area_win * self.alpha_rad_outer_win
) / (self.area_ow + self.area_rt + self.area_win)
def _calc_number_of_elements(self):
"""Calculates the number of facade elements with different tilt/orient
This function calculates the number of outer elements with a
different combination of orientation and tilt, this includes the
rooftops and ground floors.
"""
outer_elements = self.thermal_zone.outer_walls + self.thermal_zone.windows
tilt_orient = []
for element in outer_elements:
tilt_orient.append((element.orientation, element.tilt))
self.n_outer = len(list(set(tilt_orient)))
tilt_orient_rt = []
for roof in self.thermal_zone.rooftops:
tilt_orient_rt.append((roof.orientation, roof.tilt))
self.n_rt = len(list(set(tilt_orient_rt)))
def _fill_zone_lists(self):
"""Fills lists like weightfactors and tilt, orientation
Fills the lists of a zone according to orientation and tilt of the
zone. Therefore it compares orientation and tilt of all outer
elements and then creates lists for zone weightfactors, orientation,
tilt, ares and sunblinds."""
outer_elements = self.thermal_zone.outer_walls + self.thermal_zone.windows
tilt_orient = []
for element in outer_elements:
tilt_orient.append((element.orientation, element.tilt))
tilt_orient = list(set(tilt_orient))
for i in tilt_orient:
walls = self.thermal_zone.find_walls(i[0], i[1])
wins = self.thermal_zone.find_wins(i[0], i[1])
if self.merge_windows is True:
self.facade_areas.append(
sum([element.area for element in (walls + wins)])
)
else:
self.facade_areas.append(sum([element.area for element in (walls)]))
self.orientation_facade.append(i[0])
self.tilt_facade.append(i[1])
if not walls:
self.weightfactor_ow.append(0.0)
self.outer_wall_areas.append(0.0)
else:
self.weightfactor_ow.append(sum([wall.wf_out for wall in walls]))
self.outer_wall_areas.append(sum([wall.area for wall in walls]))
if not wins:
self.weightfactor_win.append(0.0)
self.shading_g_total.append(1.0)
self.window_areas.append(0.0)
self.transparent_areas.append(0.0)
else:
self.weightfactor_win.append(sum([win.wf_out for win in wins]))
if self.merge_windows is False:
self.window_areas.append(sum([win.area for win in wins]))
self.transparent_areas.append(sum([win.area for win in wins]))
else:
self.window_areas.append(0)
self.transparent_areas.append(sum([win.area for win in wins]))
self.shading_g_total.append(
sum(
[
win.shading_g_total * win.area / sum([w.area for w in wins])
for win in wins
]
)
)
self.shading_max_irr.append(
sum(
[
win.shading_max_irr * win.area / sum([w.area for w in wins])
for win in wins
]
)
)
tilt_orient_rt = []
for roof in self.thermal_zone.rooftops:
tilt_orient_rt.append((roof.orientation, roof.tilt))
tilt_orient_rt = list(set(tilt_orient_rt))
for i in tilt_orient_rt:
rts = self.thermal_zone.find_rts(i[0], i[1])
self.orientation_rt.append(i[0])
self.tilt_rt.append(i[1])
self.weightfactor_win_rt.append(0)
if not rts:
self.weightfactor_rt.append(0.0)
self.rooftop_areas.append(0.0)
else:
self.weightfactor_rt.append(sum([rt.wf_out for rt in rts]))
self.rooftop_areas.append(sum([rt.area for rt in rts]))
def _calc_heat_load(self):
"""Static heat load calculation
This function calculates the static heat load of the thermal zone by
multiplying the UA-Value of the elements with the given Temperature
difference of t_inside and t_outside. And takes heat losses through
infiltration into account.
Attributes
----------
ua_value_ow_temp : float [W/(m2*K)]
UA Value without GroundFloors
ua_value_gf_temp : float [W/(m2*K)]
UA Value of all GroundFloors
"""
if self.thermal_zone.use_conditions.base_infiltration > 0.5:
raise warnings.warn("The base_infiltration is larger than 0.5, "
"which could lead to ideal heaters being too small.")
self.heat_load = 0.0
ua_value_ow_temp = self.ua_value_rt + self.ua_value_ow
self.heat_load_outside_factor = (
(ua_value_ow_temp + self.ua_value_win)
+ self.thermal_zone.volume
* self.thermal_zone.use_conditions.normative_infiltration
* 1
/ 3600
* self.thermal_zone.heat_capac_air
* self.thermal_zone.density_air
)
self.heat_load_ground_factor = self.ua_value_gf
self.heat_load = \
self.heat_load_outside_factor \
* (self.thermal_zone.t_inside - self.thermal_zone.t_outside) \
+ self.heat_load_ground_factor \
* (self.thermal_zone.t_inside - self.thermal_zone.t_ground)
[docs]
def set_calc_default(self):
"""sets default calculation parameters
"""
# Attributes of inner walls
self.area_iw = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_iw = 0.0
self.alpha_rad_inner_iw = 0.0
self.alpha_comb_inner_iw = 0.0
# coefficient of heat transfer facing the adjacent thermal zone
self.alpha_conv_outer_iw = 0.0
self.alpha_rad_outer_iw = 0.0
self.alpha_comb_outer_iw = 0.0
# UA-Value
self.ua_value_iw = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_iw = 0.0
self.r_rad_inner_iw = 0.0
self.r_comb_inner_iw = 0.0
self.r_conv_outer_iw = 0.0
self.r_rad_outer_iw = 0.0
self.r_comb_outer_iw = 0.0
# lumped resistance/capacity
self.r1_iw = 0.0
self.c1_iw = 0.0
# Attributes for outer walls
self.area_ow = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_ow = 0.0
self.alpha_rad_inner_ow = 0.0
self.alpha_comb_inner_ow = 0.0
# coefficient of heat transfer facing the ambient
self.alpha_conv_outer_ow = 0.0
self.alpha_rad_outer_ow = 0.0
self.alpha_comb_outer_ow = 0.0
# UA-Value
self.ua_value_ow = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_ow = 0.0
self.r_rad_inner_ow = 0.0
self.r_comb_inner_ow = 0.0
# resistances for heat transfer facing the ambient
self.r_conv_outer_ow = 0.0
self.r_rad_outer_ow = 0.0
self.r_comb_outer_ow = 0.0
# lumped resistances/capacity
self.r1_ow = 0.0
self.r_rest_ow = 0.0
self.c1_ow = 0.0
self.r_total_ow = 0.0
# Optical properties
self.ir_emissivity_outer_ow = 0.0
self.ir_emissivity_inner_ow = 0.0
self.solar_absorp_ow = 0.0
# Additional attributes
self.weightfactor_ow = []
self.weightfactor_ground = 0.0
self.outer_wall_areas = []
# Attributes for GroundFloor
self.area_gf = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_gf = 0.0
self.alpha_rad_inner_gf = 0.0
self.alpha_comb_inner_gf = 0.0
# UA-Value
self.ua_value_gf = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_gf = 0.0
self.r_rad_inner_gf = 0.0
self.r_comb_inner_gf = 0.0
# lumped resistances/capacity
self.r1_gf = 0.0
self.r_rest_gf = 0.0
self.c1_gf = 0.0
self.r_total_gf = 0.0
# Optical properties
self.ir_emissivity_inner_gf = 0.0
# Additional attributes
self.weightfactor_ground = 0.0
# Attributes for rooftops
self.area_rt = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_rt = 0.0
self.alpha_rad_inner_rt = 0.0
self.alpha_comb_inner_rt = 0.0
# coefficient of heat transfer facing the ambient
self.alpha_conv_outer_rt = 0.0
self.alpha_rad_outer_rt = 0.0
self.alpha_comb_outer_rt = 0.0
# UA-Value
self.ua_value_rt = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_rt = 0.0
self.r_rad_inner_rt = 0.0
self.r_comb_inner_rt = 0.0
# resistances for heat transfer facing the ambient
self.r_conv_outer_rt = 0.0
self.r_rad_outer_rt = 0.0
self.r_comb_outer_rt = 0.0
# lumped resistances/capacity
self.r1_rt = 0.0
self.r_rest_rt = 0.0
self.c1_rt = 0.0
self.r_total_rt = 0.0
# Optical properties
self.ir_emissivity_outer_rt = 0.0
self.ir_emissivity_inner_rt = 0.0
self.solar_absorp_rt = 0.0
# Additional attributes
self.weightfactor_rt = []
self.rooftop_areas = []
self.tilt_rt = []
self.orientation_rt = []
# TODO: check this value
self.r_rad_rt_iw = 0.0
# Attributes for windows
self.area_win = 0.0
# coefficient of heat transfer facing the inside of this thermal zone
self.alpha_conv_inner_win = 0.0
self.alpha_rad_inner_win = 0.0
self.alpha_comb_inner_win = 0.0
self.ratio_conv_rad_inner_win = 0.0
# coefficient of heat transfer facing the ambient
self.alpha_conv_outer_win = 0.0
self.alpha_rad_outer_win = 0.0
self.alpha_comb_outer_win = 0.0
# UA-Value
self.ua_value_win = 0.0
self.u_value_win = 0.0
# resistances for heat transfer facing the inside of this thermal zone
self.r_conv_inner_win = 0.0
self.r_rad_inner_win = 0.0
self.r_comb_inner_win = 0.0
# resistances for heat transfer facing the ambient
self.r_conv_outer_win = 0.0
self.r_rad_outer_win = 0.0
self.r_comb_outer_win = 0.0
# lumped resistances/capacity
self.r1_win = 0.0
# Optical properties
self.ir_emissivity_win = 0.0
self.solar_absorp_win = 0.0
# Additional attributes
self.weightfactor_win = []
self.window_areas = []
self.transparent_areas = []
self.shading_g_total = []
self.shading_max_irr = []
self.weighted_g_value = 0.0
# Misc values
self.alpha_rad_inner_mean = 0.0
self.n_outer = 0
self.n_rt = 0
self.facade_areas = []
self.tilt_facade = []
self.orientation_facade = []
self.heat_load = 0.0
self.cool_load = 0.0